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Experimental Study on Time-Dependent Changes in Rheological Properties and Flow-Rate of 3D Concrete Printing Materials (2021-10)

10.3390/ma14216278

 Lee Hojae,  Seo Eun-A,  Kim Won-Woo,  Moon Jae-Heum
Journal Article - Materials, Vol. 14, Iss. 21

Abstract

Three-dimensional concrete printing (3DCP) materials require a relatively low water-to-binder ratio (W/B) of 0.3 or less to ensure their buildability and flow properties are sufficiently maintained after mixing. In this study, the rheological properties of 3DCP materials with W/B 0.28 were evaluated up to 60 min after mixing, and the yield stress and plastic viscosity were analyzed over time. A gradual decrease in flow rate with time was observed during the transport of 200 kg of material per batch through a 20 m hose. To examine the time-dependent changes in flow rate and layer volume, a 2200 mm × 1000 mm test specimen was printed. The dependence of the layer width over time during the printing process was measured and analyzed. The experimental analyses showed that the flow rate and layer volume of the 3DCP material gradually decreased with time after mixing, which was correlated with the rheological properties.

21 References

  1. Alghamdi Hussam, Nair Sooraj, Neithalath Narayanan (2019-02)
    Insights into Material-Design, Extrusion Rheology, and Properties of 3D Printable Alkali-Activated Fly-Ash-Based Binders
  2. Arunothayan Arun, Nematollahi Behzad, Bong Shin, Ranade Ravi et al. (2019-09)
    Hardened Properties of 3D Printable Ultra-High-Performance Fiber-Reinforced Concrete for Digital Construction Applications
  3. Bao Yi, Xu Mingfeng, Soltan Daniel, Xia Tian et al. (2018-09)
    Three-Dimensional Printing Multifunctional Engineered Cementitious Composites (ECC) for Structural Elements
  4. Khalil Noura, Aouad Georges, Cheikh Khadija, Rémond Sébastien (2017-09)
    Use of Calcium-Sulfoaluminate-Cements for Setting-Control of 3D Printing Mortars
  5. Le Thanh, Austin Simon, Lim Sungwoo, Buswell Richard et al. (2012-01)
    Mix-Design and Fresh Properties for High-Performance Printing Concrete
  6. Lee Hojae, Kim Jang-Ho, Moon Jae-Heum, Kim Won-Woo et al. (2019-12)
    Evaluation of the Mechanical Properties of a 3D Printed Mortar
  7. Long Wujian, Tao Jie-Lin, Lin Can, Gu Yucun et al. (2019-08)
    Rheology and Buildability of Sustainable Cement-Based Composites Containing Micro-Crystalline Cellulose for 3D Printing
  8. Ma Guowei, Li Zhijian, Wang Li, Wang Fang et al. (2019-01)
    Mechanical Anisotropy of Aligned Fiber-Reinforced Composite for Extrusion-Based 3D Printing
  9. Mechtcherine Viktor, Nerella Venkatesh, Will Frank, Näther Mathias et al. (2019-08)
    Large-Scale Digital Concrete Construction:
    CONPrint3D Concept for On-Site, Monolithic 3D Printing
  10. Panda Biranchi, Paul Suvash, Mohamed Nisar, Tay Yi et al. (2017-09)
    Measurement of Tensile Bond Strength of 3D Printed Geopolymer Mortar
  11. Rahul Attupurathu, Santhanam Manu (2020-02)
    Evaluating the Printability of Concretes Containing Lightweight Coarse Aggregates
  12. Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2018-12)
    3D Printable Concrete:
    Mixture-Design and Test-Methods
  13. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  14. Sanjayan Jay, Jayathilakage Roshan, Rajeev Pathmanathan (2020-11)
    Vibration-Induced Active Rheology-Control for 3D Concrete Printing
  15. Suntharalingam Thadshajini, Nagaratnam Brabha, Poologanathan Keerthan, Hackney Phil et al. (2020-07)
    Effect of Polypropylene-Fibers on the Mechanical Properties of Extrudable Cementitious Material
  16. Wang Weiqiang, Konstantinidis Nikolaos, Austin Simon, Buswell Richard et al. (2020-07)
    Flexural Behavior of AR-Glass-Textile-Reinforced 3D Printed Concrete Beams
  17. Weng Yiwei, Lu Bing, Li Mingyang, Liu Zhixin et al. (2018-09)
    Empirical Models to Predict Rheological Properties of Fiber-Reinforced Cementitious Composites for 3D Printing
  18. Xu Jie, Ding Lieyun, Cai Lixiong, Zhang Lichao et al. (2019-04)
    Volume-Forming 3D Concrete Printing Using a Variable-Size Square Nozzle
  19. Zhang Jingchuan, Wang Jialiang, Dong Sufen, Yu Xun et al. (2019-07)
    A Review of the Current Progress and Application of 3D Printed Concrete
  20. Zhang Yu, Zhang Yunsheng, She Wei, Yang Lin et al. (2019-01)
    Rheological and Hardened Properties of the High-Thixotropy 3D Printing Concrete
  21. Zhu Binrong, Pan Jinlong, Nematollahi Behzad, Zhou Zhenxin et al. (2019-07)
    Development of 3D Printable Engineered Cementitious Composites with Ultra-High Tensile Ductility for Digital Construction

12 Citations

  1. Jamifar Vahid, Eskandari‐Naddaf Hamid, Dehestani Mehdi (2025-10)
    Optimizing Electric Arc Furnace Dust Utilization in 3D Printed Reinforced Cement Paste Using D‐Optimal Design of Experiments and Gray Wolf Optimization
  2. Kim Ki-Yeol, Lim Dong-Kyu, Choi Myoungsung (2025-09)
    Comparison of Pumping Mechanism for Various Cementitious Materials
  3. Jiang Yu, Zhang Qingxin, Tabbaa Abir, Daly Ronan (2025-03)
    The Critical Role of Time-Dependent Rheology for Improved Quality Control of 3D Printed Cementitious Structures
  4. Yuan Yong, Fatoyinbo Imoleayo, Sheng Ruiyi, Wang Qiling et al. (2025-02)
    Advancing the Applicability of Recycled Municipal Solid Waste Incineration Bottom Ash as a Cement Substitute in Printable Concrete:
    Emphasis on Rheological and Microstructural Properties
  5. Schossler Rodrigo, Ullah Shafi, Alajlan Zaid, Yu Xiong (2025-01)
    Data-Driven Analysis in 3D Concrete Printing:
    Predicting and Optimizing Construction Mixtures
  6. Jiang Yu, Tabbaa Abir, Daly Ronan (2024-09)
    Effects of Time-Dependent Rheological Properties of Cementitious Materials on the Print Quality of Extrusion-Based 3D Printing
  7. Ramesh Akilesh, Rajeev Pathmanathan, Sanjayan Jay, Mechtcherine Viktor (2024-06)
    In-Process Textile Reinforcement Method for 3D Concrete Printing and Its Structural Performance
  8. Rehman Atta, Perrot Arnaud, Birru Bizu, Kim Jung-Hoon (2023-09)
    Recommendations for Quality-Control in Industrial 3D Concrete Printing Construction with Mono-Component Concrete:
    A Critical Evaluation of Ten Test-Methods and the Introduction of the Performance-Index
  9. Kalthoff Matthias, Raupach Michael, Matschei Thomas (2022-09)
    Investigation of Rheological Test-Methods for the Suitability of Mortars for Manufacturing of Textile-Reinforced Concrete Using a Laboratory Mortar-Extruder:
    LabMorTex
  10. Lee Keon-Woo, Lee Hojae, Choi Myoungsung (2022-07)
    Correlation Between Thixotropic Behavior and Buildability for 3D Concrete Printing
  11. Gimenez-Carbo Ester, Torres Raquel, Coll Hugo, Roig-Flores Marta et al. (2022-04)
    Preliminary Study of the Fresh and Hard Properties of UHPC That Is Used to Produce 3D Printed Mortar
  12. Lee Hojae, Seo Eun-A, Kim Won-Woo, Yang Jun-Mo et al. (2021-12)
    X-Ray CT Analysis of the Cross-Section of a 3D Printed Deformed Layer

BibTeX 
@article{lee_seo_kim_moon.2021.ESoTDCiRPaFRo3CPM,
  author            = "Hojae Lee and Eun-A Seo and Won-Woo Kim and Jae-Heum Moon",
  title             = "Experimental Study on Time-Dependent Changes in Rheological Properties and Flow-Rate of 3D Concrete Printing Materials",
  doi               = "10.3390/ma14216278",
  year              = "2021",
  journal           = "Materials",
  volume            = "14",
  number            = "21",
}
Formatted Citation

H. Lee, E.-A. Seo, W.-W. Kim and J.-H. Moon, “Experimental Study on Time-Dependent Changes in Rheological Properties and Flow-Rate of 3D Concrete Printing Materials”, Materials, vol. 14, no. 21, 2021, doi: 10.3390/ma14216278.

Lee, Hojae, Eun-A Seo, Won-Woo Kim, and Jae-Heum Moon. “Experimental Study on Time-Dependent Changes in Rheological Properties and Flow-Rate of 3D Concrete Printing Materials”. Materials 14, no. 21 (2021). https://doi.org/10.3390/ma14216278.